Cholinergic drugs
Cholinergic drugs
Are drugs act on receptors that are activated by
acetylcholine(ACH) which is the neurotransmitter of the
parasympathetic nervous system.
ACH is synthesized in the cholinergic neurons from
choline and acetyl CoA then stored in synaptic vesicles
then it will be release into synaptic gap to bind post
synaptic receptors and lead to biological response.
ACH is metabolized by acetylcholine esterase enzyme that
cleaves it to choline and acetate.
Choline will be recaptured by uptake system back into the
neuron and recycling will occur.
•Cholinergic receptors( cholinoceptors ) are two
families muscarinic and nicotinic depending on
their affinities to cholinomimetic agents(agents that
mimic ACH actions).
Muscarinic receptors bind ACH and also recognize
muscarine, they are located in autonomic effector
organs such as heart, smooth muscle, brain, and
exocrine glands.
Nicotinic receptors bind ACH and also recognize
nicotine. They are located in the CNS, adrenal
medulla, autonomic ganglia, and neuromuscular
junction.
Direct acting cholinergic agonists:
Are agents mimic the effect of ACH by binding directly to
cholinoceptors.
They are synthetic esters of choline such as carbachol and
bethanechol or naturally occurring alkaloids such as
pilocarpine.
All of these drugs have longer duration of action than
ACH.
ACH:
Is the neurotransmitter of the parasympathetic N.S and
cholinergic nerves, it is therapeutically of no importance
due to:
1. Multiplicity of actions.
2. Rapid inactivation by acetyl-cholinesterase.
3. Has both muscarinic and nicotinic activity.
Actions:
Decrease in heart rate and cardiac output: Due to SA node
depression.
Decrease in blood pressure: It causes vasodilatation due to its
effect on cholinergic receptors in blood vessels, it will lead to
increase in intracellular nitric oxide (NO) which is called
endothelium derived relaxing factor (EDRF).
Other actions:
GIT: Increase salivary secretion and increase intestinal motility
and secretion.
Respiratory: stimulate bronchiolar secretions.
Genitourinary tract: Increase detrusor muscle tone.
Eye: Miosis (marked constriction of the pupil
Bethanechol:
Structurally related to ACH, has strong muscarinic activity
but no nicotinic actions.
It directly stimulates muscarinic receptors of the GIT causing
increase intestinal motility and tone, it also stimulates
detrusor muscle of the bladder causing urine expulsion.
Clinical uses:
1.Atonic bladder stimulation such as in
postpartum and post operative non
obstructive urine retention.
Side effects: Sweating, salivation, flushing,
hypotension, nausea, abdominal pain,
diarrhea, and bronchospasm.
Carbachol:
Has both muscarinic and nicotinic
actions, has strong effect on CVS and
GIT, it causes release of epinephrine
from adrenal medulla by its nicotinic
action,using it locally on the eye cause
Miosis.
Clinical uses:
Rarely used because of high potency
and long duration of action except in
the eye to cause Miosis and to
decrease intraocular pressure.
Pilocarpine: Mainly used in ophthalmology, it exhibit
muscarinic activity, it produces rapid
miosis and contraction of the ciliary
muscle.
Clinical uses:
It is the drug of choice in the emergency
lowering of inrtra-ocular pressure in
case of glaucoma.
Side effects:
It can enter the brain and cause
CNS disturbances, it stimulate
profuse sweating and salivation.
Indirect acting cholinergic agonists:
Are drugs that exert cholinergic actions by prolonging the
life time of ACH via inhibition of acetyl-cholinesterase
enzyme, this results in accumulation of ACH in synaptic
space and provoke response at all cholinoceptors in the
body including both muscarinic and nicotinic receptors as
well as neuromuscular junction and the brain, these drugs
are termed (anti-cholinesterases) which are reversible and
irreversible.
Reversible anticholinesterase
•This group include: physostigmine, neostigmine, pyridostigmine, and edrophonium, ambenonium, and demecarium. The major therapeutic uses of the cholinomimetics are for diseases of the eye (glaucoma, accommodative esotropia), the gastrointestinal and urinary tracts (postoperative atony, neurogenic bladder), neuromuscular junction (myasthenia gravis, curare-induced neuromuscular paralysis), and very rarely, the heart (certain atrial arrhythmias).
•Cholinesterase inhibitors are occasionally used in the treatment of atropine overdosage. Several newer cholinesterase inhibitors are being used to treat patients with Alzheimer's disease.
Physostgmine: It is an alkaloid which is nitrogenous compound found in plants, it is a reversible inhibitor of acetylcholinesterase and potentiate cholinergic activity through out the body. Physostigmine stimulates muscarinic and nicotinic receptors of ANS and nicotinic receptors of neuromuscular junction, its duration of action is 2-4 hours, it can enter and stimulate CNS.
Clinical uses: 1. Bladder and intestinal atony (increase their motility). 2.Glaucoma ( decrease intraocular pressue). 3.Overdose of anticholinergic drugs like atropine, phenothiazines, and tricyclic antidepressants.
Side effects: 1.Convulsion at high doses. 2. Bradycardia. 3. Skeletal muscle paralysis due to inhibition of acetylcholinesterase at neuromuscular junction and ACH accumulation
Neostigmine: Synthetic compound reversibly inhibits acetylcholinesterase, it does not enter CNS, it has greater effect on skeletal muscle that can increase contractility then paralysis. Uses: 1.stimulate atonic bladder and intestine. 2.Antidote for neuromuscular blocking agents like tubocurarine. 3.Symptomatic treatment in myasthenia gravis. Side effects: Salivation, flushing, hypotension, nausea, abdominal pain, diarrhea, and bronchospasm.
Pyridostigmine: Used in chronic treatment of myasthenia gravis, its duration of action 3-6 hours.
Edrophonium: Has short duration of action (10-20 minutes) used in diagnosis of myasthenia gravis (i.v injection of edrophonium lead to rapid increase in muscle strength).
Edrophonium is sometimes used as a diagnostic test for myasthenia. A 2 mg dose is injected intravenously after baseline muscle strength has been measured. If no reaction occurs after 45 seconds, an additional 8 mg may be injected. If the patient has myasthenia gravis, an improvement in muscle strength that lasts about 5 minutes can usually be observed.
Edrophonium is also used to assess the adequacy of treatment with the longer-acting cholinesterase inhibitors in patients with myasthenia gravis. If excessive amounts of cholinesterase inhibitor have been used, patients may become paradoxically weak because of nicotinic depolarizing blockade of the motor end plate.
Clinical situations in which severe myasthenia (myasthenic crisis) must be distinguished from excessive drug therapy (cholinergic crisis) usually occur in very ill myasthenic patients and must be managed in hospital with adequate emergency support systems such as mechanical ventilators.
Long-term therapy for myasthenia gravis is usually accomplished with pyridostigmine; neostigmine. The doses are titrated to optimum levels based on changes in muscle strength. These drugs are relatively short-acting and therefore require frequent dosing (every 6 hours for pyridostigmine and every 4 hours for neostigmine.
Irreversible anticholinesterase
Are synthetic organophosphorus compounds bind acetylcholinesterase covalently and inhibit it irreversibly, so there will be increase in ACH at all the sites of its release.
These drugs are extremely toxic and used in military as nerve agents (soman, sarin, VX), some agents like parathion and malathion used as insecticides. The covalent phosphorus-enzyme bond is extremely stable and hydrolyzes in water at a very slow rate (hundreds of hours). After the initial binding-hydrolysis step, the phosphorylated enzyme complex may undergo a process called aging.
This process apparently involves the breaking of one of the oxygen-phosphorus bonds of the inhibitor and further strengthens the phosphorus-enzyme bond. The rate of aging varies with the particular organophosphate compound. If given before aging has occurred, strong nucleophiles like pralidoxime are able to break the phosphorus-enzyme bond and can be used as "cholinesterase regenerator".
Once aging has occurred, the enzyme-inhibitor complex is even more stable and is more difficult to break, even with oxime regenerator compounds.
Isoflurophate: This drug cause permanent inactivation of acetylcholinesterase , the restoration of enzyme activity requires synthesis of new enzyme molecules. It cause generalized cholinergic stimulation, paralysis of motor function leading to breathing difficulties, convulsion. It cause intense miosis, atropine in high dose can reverse its muscarinic and central effects.
Clinical uses: Available as ointment used topically for the treatment of glaucoma, the effect may last for one week after a single administration. Echothiophate also is an irreversible inhibitor of acetylcholinestrase with the same uses of isoflurophate. The inhibited acetylcholinesterase can be reactivated by pralidoxime which is synthetic compound can regenerate new enzyme.
Organophosphorus poisoning Acute intoxication must be recognized and treated promptly . The dominant initial signs are those of muscarinic excess: miosis, salivation, sweating, bronchial constriction, vomiting, and diarrhea. Central nervous system involvement (cognitive disturbances, convulsions, and coma) usually follows rapidly, accompanied by peripheral nicotinic effects.
Treatment: 1.maintenance of vital signs—respiration in particular may be impaired; (2) decontamination to prevent further absorption—this may require removal of all clothing and washing of the skin in cases of exposure to dusts and sprays; (3) atropine parenterally in large doses, given as often as required to control signs of muscarinic excess. Therapy often also includes treatment with pralidoxime and administration of benzodiazepines for seizures.